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MuonTrackAnalyzer.cc
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1 
8 
9 // Collaborating Class Header
14 
16 
20 
22 
24 
28 
31 
32 #include "TFile.h"
33 #include "TH1F.h"
34 #include "TH2F.h"
35 
36 using namespace std;
37 using namespace edm;
38 
41 
42  // service parameters
43  pset = ps;
44  ParameterSet serviceParameters = pset.getParameter<ParameterSet>("ServiceParameters");
45  // the services
46  theService = new MuonServiceProxy(serviceParameters);
47 
48  theSimTracksLabel = edm::InputTag("g4SimHits");
49  theSimTracksToken = consumes<edm::SimTrackContainer>(theSimTracksLabel);
50 
51  theTracksLabel = pset.getParameter<InputTag>("Tracks");
52  theTracksToken = consumes<reco::TrackCollection>(theTracksLabel);
53  doTracksAnalysis = pset.getUntrackedParameter<bool>("DoTracksAnalysis",true);
54 
55  doSeedsAnalysis = pset.getUntrackedParameter<bool>("DoSeedsAnalysis",false);
56  if(doSeedsAnalysis){
57  theSeedsLabel = pset.getParameter<InputTag>("MuonSeed");
58  theSeedsToken = consumes<TrajectorySeedCollection>(theSeedsLabel);
59  ParameterSet updatorPar = pset.getParameter<ParameterSet>("MuonUpdatorAtVertexParameters");
60  theSeedPropagatorName = updatorPar.getParameter<string>("Propagator");
61 
62  theUpdator = new MuonUpdatorAtVertex(updatorPar,theService);
63  }
64 
65  theCSCSimHitLabel = pset.getParameter<InputTag>("CSCSimHit");
66  theDTSimHitLabel = pset.getParameter<InputTag>("DTSimHit");
67  theRPCSimHitLabel = pset.getParameter<InputTag>("RPCSimHit");
68  theCSCSimHitToken = consumes<std::vector<PSimHit> >(theCSCSimHitLabel);
69  theDTSimHitToken = consumes<std::vector<PSimHit> >(theDTSimHitLabel);
70  theRPCSimHitToken = consumes<std::vector<PSimHit> >(theRPCSimHitLabel);
71 
72  theEtaRange = (EtaRange) pset.getParameter<int>("EtaRange");
73 
74  // number of sim tracks
75  numberOfSimTracks=0;
76  // number of reco tracks
77  numberOfRecTracks=0;
78 
80  out = pset.getUntrackedParameter<string>("rootFileName");
81  dirName_ = pset.getUntrackedParameter<std::string>("dirName");
82  subsystemname_ = pset.getUntrackedParameter<std::string>("subSystemFolder", "YourSubsystem") ;
83 }
84 
87  if (theService) delete theService;
88 }
89 
91 
92  //theFile->cd();
93 }
95  edm::Run const & iRun,
96  edm::EventSetup const & /* iSetup */){
97 
98  ibooker.cd();
99 
100 
101  InputTag algo = theTracksLabel;
102  string dirName=dirName_;
103  if (algo.process()!="")
104  dirName+=algo.process()+"_";
105  if(algo.label()!="")
106  dirName+=algo.label()+"_";
107  if(algo.instance()!="")
108  dirName+=algo.instance()+"";
109  if (dirName.find("Tracks")<dirName.length()){
110  dirName.replace(dirName.find("Tracks"),6,"");
111  }
112  std::replace(dirName.begin(), dirName.end(), ':', '_');
113  ibooker.setCurrentFolder(dirName);
114 
115  //ibooker.goUp();
116  std::string simName = dirName;
117  simName+="/SimTracks";
118  hSimTracks = new HTrackVariables(ibooker,simName,"SimTracks");
119 
120  ibooker.cd();
121  ibooker.setCurrentFolder(dirName);
122 
123  // Create the root file
124  //theFile = new TFile(theRootFileName.c_str(), "RECREATE");
125 
126  if(doSeedsAnalysis){
127  ibooker.cd();
128  ibooker.setCurrentFolder(dirName);
129  hRecoSeedInner = new HTrack(ibooker,dirName,"RecoSeed","Inner");
130  hRecoSeedPCA = new HTrack(ibooker,dirName,"RecoSeed","PCA");
131  }
132 
133  if(doTracksAnalysis){
134  ibooker.cd();
135  ibooker.setCurrentFolder(dirName);
136  hRecoTracksPCA = new HTrack(ibooker,dirName,"RecoTracks","PCA");
137  hRecoTracksInner = new HTrack(ibooker,dirName,"RecoTracks","Inner");
138  hRecoTracksOuter = new HTrack(ibooker,dirName,"RecoTracks","Outer");
139 
140  ibooker.cd();
141  ibooker.setCurrentFolder(dirName);
142 
143  // General Histos
144 
145 
146  hChi2 = ibooker.book1D("chi2","#chi^2",200,0,200);
147  hChi2VsEta = ibooker.book2D("chi2VsEta","#chi^2 VS #eta",120,-3.,3.,200,0,200);
148 
149  hChi2Norm = ibooker.book1D("chi2Norm","Normalized #chi^2",400,0,100);
150  hChi2NormVsEta = ibooker.book2D("chi2NormVsEta","Normalized #chi^2 VS #eta",120,-3.,3.,400,0,100);
151 
152  hHitsPerTrack = ibooker.book1D("HitsPerTrack","Number of hits per track",55,0,55);
153  hHitsPerTrackVsEta = ibooker.book2D("HitsPerTrackVsEta","Number of hits per track VS #eta",
154  120,-3.,3.,55,0,55);
155 
156  hDof = ibooker.book1D("dof","Number of Degree of Freedom",55,0,55);
157  hDofVsEta = ibooker.book2D("dofVsEta","Number of Degree of Freedom VS #eta",120,-3.,3.,55,0,55);
158 
159  hChi2Prob = ibooker.book1D("chi2Prob","#chi^2 probability",200,0,1);
160  hChi2ProbVsEta = ibooker.book2D("chi2ProbVsEta","#chi^2 probability VS #eta",120,-3.,3.,200,0,1);
161 
162  hNumberOfTracks = ibooker.book1D("NumberOfTracks","Number of reconstructed tracks per event",200,0,200);
163  hNumberOfTracksVsEta = ibooker.book2D("NumberOfTracksVsEta",
164  "Number of reconstructed tracks per event VS #eta",
165  120,-3.,3.,10,0,10);
166 
167  hChargeVsEta = ibooker.book2D("ChargeVsEta","Charge vs #eta gen",120,-3.,3.,4,-2.,2.);
168  hChargeVsPt = ibooker.book2D("ChargeVsPt","Charge vs P_{T} gen",250,0,200,4,-2.,2.);
169  hPtRecVsPtGen = ibooker.book2D("PtRecVsPtGen","P_{T} rec vs P_{T} gen",250,0,200,250,0,200);
170 
171  hDeltaPtVsEta = ibooker.book2D("DeltaPtVsEta","#Delta P_{t} vs #eta gen",120,-3.,3.,500,-250.,250.);
172  hDeltaPt_In_Out_VsEta = ibooker.book2D("DeltaPt_In_Out_VsEta_","P^{in}_{t} - P^{out}_{t} vs #eta gen",120,-3.,3.,500,-250.,250.);
173  }
174 
175 }
176 
178  LogInfo("MuonTrackAnalyzer")<< "Number of Sim tracks: " << numberOfSimTracks;
179 
180  LogInfo("MuonTrackAnalyzer") << "Number of Reco tracks: " << numberOfRecTracks;
181 
182 
183  if(doTracksAnalysis){
184  double eff = hRecoTracksPCA->computeEfficiency(hSimTracks,ibooker);
185  LogInfo("MuonTrackAnalyzer") <<" *Track Efficiency* = "<< eff <<"%";
186  }
187 
188  if(doSeedsAnalysis){
189  double eff = hRecoSeedInner->computeEfficiency(hSimTracks,ibooker);
190  LogInfo("MuonTrackAnalyzer")<<" *Seed Efficiency* = "<< eff <<"%";
191  }
192  if ( !out.empty() && dbe_ ) dbe_->save(out);
193 }
194 void MuonTrackAnalyzer::analyze(const Event & event, const EventSetup& eventSetup){
195 
196  LogDebug("MuonTrackAnalyzer") << "Run: " << event.id().run() << " Event: " << event.id().event();
197 
198  // Update the services
199  theService->update(eventSetup);
200 
202  event.getByToken(theSimTracksToken,simTracks);
203  fillPlots(event,simTracks);
204 
205 
206  if(doTracksAnalysis)
207  tracksAnalysis(event,eventSetup,simTracks);
208 
209  if(doSeedsAnalysis)
210  seedsAnalysis(event,eventSetup,simTracks);
211 
212 
213 }
214 
215 void MuonTrackAnalyzer::seedsAnalysis(const Event & event, const EventSetup& eventSetup,
217 
219 
220  // Get the RecTrack collection from the event
222  event.getByToken(theSeedsToken, seeds);
223 
224  LogTrace("MuonTrackAnalyzer")<<"Number of reconstructed seeds: " << seeds->size()<<endl;
225 
226  for(TrajectorySeedCollection::const_iterator seed = seeds->begin();
227  seed != seeds->end(); ++seed){
228  TrajectoryStateOnSurface seedTSOS = getSeedTSOS(*seed);
229  pair<SimTrack,double> sim = getSimTrack(seedTSOS,simTracks);
230  fillPlots(seedTSOS, sim.first,
231  hRecoSeedInner, debug);
232 
233  std::pair<bool,FreeTrajectoryState> propSeed =
234  theUpdator->propagateToNominalLine(seedTSOS);
235  if(propSeed.first)
236  fillPlots(propSeed.second, sim.first,
237  hRecoSeedPCA, debug);
238  else
239  LogTrace("MuonTrackAnalyzer")<<"Error in seed propagation"<<endl;
240 
241  }
242 }
243 
244 
245 void MuonTrackAnalyzer::tracksAnalysis(const Event & event, const EventSetup& eventSetup,
248 
249 
250  // Get the RecTrack collection from the event
252  event.getByToken(theTracksToken, tracks);
253 
254  LogTrace("MuonTrackAnalyzer")<<"Reconstructed tracks: " << tracks->size() << endl;
255  hNumberOfTracks->Fill(tracks->size());
256 
257  if(!tracks->empty()) numberOfRecTracks++;
258 
259  // Loop over the Rec tracks
260  for(reco::TrackCollection::const_iterator t = tracks->begin(); t != tracks->end(); ++t) {
261 
262  reco::TransientTrack track(*t,&*theService->magneticField(),theService->trackingGeometry());
263 
264  TrajectoryStateOnSurface outerTSOS = track.outermostMeasurementState();
265  TrajectoryStateOnSurface innerTSOS = track.innermostMeasurementState();
266  TrajectoryStateOnSurface pcaTSOS = track.impactPointState();
267 
268  pair<SimTrack,double> sim = getSimTrack(pcaTSOS,simTracks);
269  SimTrack simTrack = sim.first;
270  hNumberOfTracksVsEta->Fill(simTrack.momentum().eta(), tracks->size());
271  fillPlots(track,simTrack);
272 
273  LogTrace("MuonTrackAnalyzer") << "State at the outer surface: " << endl;
274  fillPlots(outerTSOS,simTrack,hRecoTracksOuter,debug);
275 
276  LogTrace("MuonTrackAnalyzer") << "State at the inner surface: " << endl;
277  fillPlots(innerTSOS,simTrack,hRecoTracksInner,debug);
278 
279  LogTrace("MuonTrackAnalyzer") << "State at PCA: " << endl;
280  fillPlots(pcaTSOS,simTrack,hRecoTracksPCA,debug);
281 
282  double deltaPt_in_out = innerTSOS.globalMomentum().perp()-outerTSOS.globalMomentum().perp();
283  hDeltaPt_In_Out_VsEta->Fill(simTrack.momentum().eta(),deltaPt_in_out);
284 
285  double deltaPt_pca_sim = pcaTSOS.globalMomentum().perp()-sqrt(simTrack.momentum().Perp2());
286  hDeltaPtVsEta->Fill(simTrack.momentum().eta(),deltaPt_pca_sim);
287 
288  hChargeVsEta->Fill(simTrack.momentum().eta(),pcaTSOS.charge());
289 
290  hChargeVsPt->Fill(sqrt(simTrack.momentum().perp2()),pcaTSOS.charge());
291 
292  hPtRecVsPtGen->Fill(sqrt(simTrack.momentum().perp2()),pcaTSOS.globalMomentum().perp());
293  }
294  LogTrace("MuonTrackAnalyzer")<<"--------------------------------------------"<<endl;
295 }
296 
297 
298 
299 
301 
302  if(!checkMuonSimHitPresence(event,simTracks)) return;
303 
304  // Loop over the Sim tracks
305  SimTrackContainer::const_iterator simTrack;
306  LogTrace("MuonTrackAnalyzer")<<"Simulated tracks: "<<simTracks->size()<<endl;
307 
308  for (simTrack = simTracks->begin(); simTrack != simTracks->end(); ++simTrack)
309  if (abs((*simTrack).type()) == 13) {
310 
311  if( !isInTheAcceptance( (*simTrack).momentum().eta()) ) continue; // FIXME!!
312 
313  numberOfSimTracks++;
314 
315  LogTrace("MuonTrackAnalyzer")<<"Simualted muon:"<<endl;
316  LogTrace("MuonTrackAnalyzer")<<"Sim pT: "<<sqrt((*simTrack).momentum().perp2())<<endl;
317  LogTrace("MuonTrackAnalyzer")<<"Sim Eta: "<<(*simTrack).momentum().eta()<<endl; // FIXME
318 
319  hSimTracks->Fill((*simTrack).momentum().mag(),
320  sqrt((*simTrack).momentum().perp2()),
321  (*simTrack).momentum().eta(),
322  (*simTrack).momentum().phi(),
323  -(*simTrack).type()/ abs((*simTrack).type()) ); // Double FIXME
324  LogTrace("MuonTrackAnalyzer") << "hSimTracks filled" << endl;
325  }
326 
327  LogTrace("MuonTrackAnalyzer") << endl;
328 }
329 
330 
332 
333  LogTrace("MuonTrackAnalyzer")<<"Analizer: New track, chi2: "<<track.chi2()<<" dof: "<<track.ndof()<<endl;
334  hChi2->Fill(track.chi2());
335  hDof->Fill(track.ndof());
336  hChi2Norm->Fill(track.normalizedChi2());
337  hHitsPerTrack->Fill(track.recHitsSize());
338 
339  hChi2Prob->Fill( ChiSquaredProbability(track.chi2(),track.ndof()) );
340 
341  hChi2VsEta->Fill(simTrack.momentum().eta(),track.chi2());
342  hChi2NormVsEta->Fill(simTrack.momentum().eta(),track.normalizedChi2());
343  hChi2ProbVsEta->Fill(simTrack.momentum().eta(),ChiSquaredProbability(track.chi2(),track.ndof()));
344  hHitsPerTrackVsEta->Fill(simTrack.momentum().eta(),track.recHitsSize());
345  hDofVsEta->Fill(simTrack.momentum().eta(),track.ndof());
346 }
347 
348 
351 
352  LogTrace("MuonTrackAnalyzer") << debug.dumpTSOS(recoTSOS)<<endl;
353  histo->Fill(recoTSOS);
354 
355  GlobalVector tsosVect = recoTSOS.globalMomentum();
356  math::XYZVectorD reco(tsosVect.x(), tsosVect.y(), tsosVect.z());
357  double deltaRVal = deltaR<double>(reco.eta(),reco.phi(),
358  simTrack.momentum().eta(),simTrack.momentum().phi());
359  histo->FillDeltaR(deltaRVal);
360 
361  histo->computeResolutionAndPull(recoTSOS,simTrack);
362 }
363 
364 
367 
368  LogTrace("MuonTrackAnalyzer") << debug.dumpFTS(recoFTS)<<endl;
369  histo->Fill(recoFTS);
370 
371  GlobalVector ftsVect = recoFTS.momentum();
372  math::XYZVectorD reco(ftsVect.x(), ftsVect.y(), ftsVect.z());
373  double deltaRVal = deltaR<double>(reco.eta(),reco.phi(),
374  simTrack.momentum().eta(),simTrack.momentum().phi());
375  histo->FillDeltaR(deltaRVal);
376 
377  histo->computeResolutionAndPull(recoFTS,simTrack);
378 }
379 
382 
383 // // Loop over the Sim tracks
384 // SimTrackContainer::const_iterator simTrack;
385 
386 // SimTrack result;
387 // int mu=0;
388 // for (simTrack = simTracks->begin(); simTrack != simTracks->end(); ++simTrack)
389 // if (abs((*simTrack).type()) == 13) {
390 // result = *simTrack;
391 // ++mu;
392 // }
393 
394 // if(mu != 1) LogTrace("MuonTrackAnalyzer") << "WARNING!! more than 1 simulated muon!!" <<endl;
395 // return result;
396 
397 
398  // Loop over the Sim tracks
399  SimTrackContainer::const_iterator simTrack;
400 
402 
403  double bestDeltaR = 10e5;
404  for (simTrack = simTracks->begin(); simTrack != simTracks->end(); ++simTrack){
405  if (abs((*simTrack).type()) != 13) continue;
406 
407  // double newDeltaR = tsos.globalMomentum().basicVector().deltaR(simTrack->momentum().vect());
408  GlobalVector tsosVect = tsos.globalMomentum();
409  math::XYZVectorD vect(tsosVect.x(), tsosVect.y(), tsosVect.z());
410  double newDeltaR = deltaR<double>(vect.eta(),vect.phi(),
411  simTrack->momentum().eta(),simTrack->momentum().phi());
412 
413  if ( newDeltaR < bestDeltaR ) {
414  LogTrace("MuonTrackAnalyzer") << "Matching Track with DeltaR = " << newDeltaR<<endl;
415  bestDeltaR = newDeltaR;
416  result = *simTrack;
417  }
418  }
419  return pair<SimTrack,double>(result,bestDeltaR);
420 }
421 
422 
424  switch(theEtaRange){
425  case all:
426  return ( abs(eta) <= 2.4 ) ? true : false;
427  case barrel:
428  return ( abs(eta) < 1.1 ) ? true : false;
429  case endcap:
430  return ( abs(eta) >= 1.1 && abs(eta) <= 2.4 ) ? true : false;
431  default:
432  {LogTrace("MuonTrackAnalyzer")<<"No correct Eta range selected!! "<<endl; return false;}
433  }
434 }
435 
438 
439  // Get the SimHit collection from the event
440  Handle<PSimHitContainer> dtSimHits;
441  event.getByToken(theDTSimHitToken, dtSimHits);
442 
443 
444  Handle<PSimHitContainer> cscSimHits;
445  event.getByToken(theCSCSimHitToken, cscSimHits);
446 
447  Handle<PSimHitContainer> rpcSimHits;
448  event.getByToken(theRPCSimHitToken, rpcSimHits);
449 
450  map<unsigned int, vector<const PSimHit*> > mapOfMuonSimHits;
451 
452  for(PSimHitContainer::const_iterator simhit = dtSimHits->begin();
453  simhit != dtSimHits->end(); ++simhit) {
454  if (abs(simhit->particleType()) != 13) continue;
455  mapOfMuonSimHits[simhit->trackId()].push_back(&*simhit);
456  }
457 
458  for(PSimHitContainer::const_iterator simhit = cscSimHits->begin();
459  simhit != cscSimHits->end(); ++simhit) {
460  if (abs(simhit->particleType()) != 13) continue;
461  mapOfMuonSimHits[simhit->trackId()].push_back(&*simhit);
462  }
463 
464  for(PSimHitContainer::const_iterator simhit = rpcSimHits->begin();
465  simhit != rpcSimHits->end(); ++simhit) {
466  if (abs(simhit->particleType()) != 13) continue;
467  mapOfMuonSimHits[simhit->trackId()].push_back(&*simhit);
468  }
469 
470  bool presence = false;
471 
472  for (SimTrackContainer::const_iterator simTrack = simTracks->begin();
473  simTrack != simTracks->end(); ++simTrack){
474 
475  if (abs(simTrack->type()) != 13) continue;
476 
477  map<unsigned int, vector<const PSimHit*> >::const_iterator mapIterator =
478  mapOfMuonSimHits.find(simTrack->trackId());
479 
480  if (mapIterator != mapOfMuonSimHits.end())
481  presence = true;
482  }
483 
484  return presence;
485 }
486 
488 
489  // Get the Trajectory State on Det (persistent version of a TSOS) from the seed
490  PTrajectoryStateOnDet pTSOD = seed.startingState();
491 
492  // Transform it in a TrajectoryStateOnSurface
493 
494 
495  DetId seedDetId(pTSOD.detId());
496 
497  const GeomDet* gdet = theService->trackingGeometry()->idToDet( seedDetId );
498 
499  TrajectoryStateOnSurface initialState = trajectoryStateTransform::transientState(pTSOD, &(gdet->surface()), &*theService->magneticField());
500 
501  // Get the layer on which the seed relies
502  const DetLayer *initialLayer = theService->detLayerGeometry()->idToLayer( seedDetId );
503 
505 
506  // ask for compatible layers
507  vector<const DetLayer*> detLayers;
508  detLayers = theService->muonNavigationSchool()->compatibleLayers(*initialLayer, *initialState.freeState(),detLayerOrder);
509 
510  TrajectoryStateOnSurface result = initialState;
511  if(!detLayers.empty()){
512  const DetLayer* finalLayer = detLayers.back();
513  const TrajectoryStateOnSurface propagatedState = theService->propagator(theSeedPropagatorName)->propagate(initialState, finalLayer->surface());
514  if(propagatedState.isValid())
515  result = propagatedState;
516  }
517 
518  return result;
519 }
#define LogDebug(id)
T getParameter(std::string const &) const
void computeResolutionAndPull(TrajectoryStateOnSurface &vtx, SimTrack &simTrack)
Definition: HTrack.cc:146
T perp() const
Definition: PV3DBase.h:72
std::pair< SimTrack, double > getSimTrack(TrajectoryStateOnSurface &tsos, edm::Handle< edm::SimTrackContainer > simTracks)
bool checkMuonSimHitPresence(const edm::Event &event, edm::Handle< edm::SimTrackContainer > simTracks)
T y() const
Definition: PV3DBase.h:63
def replace(string, replacements)
size_t recHitsSize() const
number of RecHits
PropagationDirection
TrajectoryStateOnSurface getSeedTSOS(const TrajectorySeed &seed)
void seedsAnalysis(const edm::Event &event, const edm::EventSetup &eventSetup, edm::Handle< edm::SimTrackContainer > simTracks)
double chi2() const
chi-squared of the fit
MuonTrackAnalyzer(const edm::ParameterSet &pset)
Constructor.
std::string dumpFTS(const FreeTrajectoryState &fts) const
std::string dumpTSOS(const TrajectoryStateOnSurface &tsos) const
void beginJob() override
ROOT::Math::DisplacementVector3D< ROOT::Math::Cartesian3D< double > > XYZVectorD
spatial vector with cartesian internal representation
Definition: Vector3D.h:8
void endRun(DQMStore::IBooker &ibooker)
simTrack
per collection params
T sqrt(T t)
Definition: SSEVec.h:18
bool isInTheAcceptance(double eta)
FreeTrajectoryState const * freeState(bool withErrors=true) const
T z() const
Definition: PV3DBase.h:64
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:118
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
virtual const BoundSurface & surface() const =0
The surface of the GeometricSearchDet.
float ChiSquaredProbability(double chiSquared, double nrDOF)
unsigned int detId() const
TH1F * hChi2
void Fill(TrajectoryStateOnSurface &)
Definition: HTrack.cc:123
GlobalVector momentum() const
#define LogTrace(id)
DQMStore * dbe_
Definition: RunManager.h:28
Definition: DetId.h:18
PTrajectoryStateOnDet const & startingState() const
#define debug
Definition: HDRShower.cc:19
void setCurrentFolder(const std::string &fullpath)
Definition: DQMStore.cc:279
TrajectoryStateOnSurface transientState(const PTrajectoryStateOnDet &ts, const Surface *surface, const MagneticField *field)
MonitorElement * book2D(Args &&...args)
Definition: DQMStore.h:136
void bookHistograms(DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
double normalizedChi2() const
chi-squared divided by n.d.o.f.
std::string const & label() const
Definition: InputTag.h:36
double ndof() const
number of degrees of freedom of the fit
std::string const & process() const
Definition: InputTag.h:40
void tracksAnalysis(const edm::Event &event, const edm::EventSetup &eventSetup, edm::Handle< edm::SimTrackContainer > simTracks)
fixed size matrix
HLT enums.
GlobalVector globalMomentum() const
const math::XYZTLorentzVectorD & momentum() const
Definition: CoreSimTrack.h:22
~MuonTrackAnalyzer() override
Destructor.
void analyze(const edm::Event &event, const edm::EventSetup &eventSetup) override
void FillDeltaR(double)
Definition: HTrack.cc:136
T x() const
Definition: PV3DBase.h:62
Definition: HTrack.h:14
std::string const & instance() const
Definition: InputTag.h:37
void fillPlots(const edm::Event &event, edm::Handle< edm::SimTrackContainer > &simTracks)
Definition: event.py:1
Definition: Run.h:43